MAXIM MAX5953DUTM

19-3945; Rev 1; 7/06
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
The MAX5953A/MAX5953B/MAX5953C/MAX5953D
integrate a complete power IC solution for Powered
Devices (PD) in a Power-Over-Ethernet (PoE) system, in
compliance with the IEEE 802.3af standard. The
MAX5953A/MAX5953B/MAX5953C/MAX5953D provide
the PD with a detection signature, a classification signature, and an integrated isolation switch with programmable inrush current control. These devices also
integrate a voltage-mode PWM controller with two
power MOSFETs connected in a two-switch voltageclamped DC-DC converter configuration.
An integrated MOSFET provides PD isolation during
detection and classification. All devices guarantee a
leakage current offset of less than 10µA during the
detection phase. A programmable current limit prevents high inrush current during power-on. The devices
feature power-mode undervoltage lockout (UVLO) with
wide hysteresis and long deglitch time to compensate
for twisted-pair-cable resistive drop and to assure
glitch-free transition between detection, classification,
and power-on/-off phases. The MAX5953A/MAX5953C
have an adjustable UVLO threshold with the default
value compliant to the 802.3af standard, while the
MAX5953B/MAX5953D have a lower and fixed UVLO
threshold compatible with some legacy pre-802.3af
power-sourcing equipment (PSE) devices.
The DC-DC converters are operable in either forward or
flyback configurations with a wide input voltage range
from 11V to 76V and up to 15W of output power. The
voltage-clamped power topology enables full recovery
of stored magnetizing and leakage inductive energy for
enhanced efficiency and reliability. When using the
high-side MOSFET, the controller can be configured as
a buck converter. A look-ahead signal for driving secondary-side synchronous rectifiers can be used to
increase efficiency. A wide array of protection features
include UVLO, over-temperature shutdown, and shortcircuit protection with hiccup current limit for enhanced
performance and reliability. Operation up to 500kHz
allows for smaller external magnetics and capacitors.
The MAX5953A/MAX5953B/MAX5953C/MAX5953D are
available in a high-power (2.22W), 7mm x 7mm thermally enhanced thin QFN package.
Applications
IEEE 802.3af Powered
Devices
IP Phones
Wireless Access Nodes
Internet Appliances
Security Cameras
Computer Telephony
Features
♦ Powered Device Interface
Fully Integrated IEEE 802.3af-Compliant PD
Interface
PD Detection and Programmable Classification
Signatures
Less than 10µA Leakage Current Offset During
Detection
Integrated MOSFET for Isolation and Inrush
Current Limiting
Gate Output Allows External Control of the
Internal Isolation MOSFET
Programmable Inrush Current Control
Programmable Undervoltage Lockout
(MAX5953A/MAX5953C)
♦ DC-DC Converter
Clamped, Two-Switch Power IC for High
Efficiency
Integrated High-Voltage 0.4Ω Power MOSFETs
Up to 15W Output Power
Bias Voltage Regulator with Automatic HighVoltage Supply Turn-Off
11V to 76V Wide Input Voltage Range
Feed-Forward Voltage-Mode Control for Fast
Input Transient Rejection
Programmable Undervoltage Lockout
Overtemperature Shutdown
Indefinite Short-Circuit Protection with
Programmable Fault Integration
Integrated Look-Ahead Signal for SecondarySide Synchronous Rectification
> 90% Efficiency with Synchronous
Rectification
Up to 500kHz Switching Frequency
♦ High-Power (2.22W), 7mm x 7mm Thermally
Enhanced Lead-Free Thin QFN Package
Ordering Information
PIN-PACKAGE
PKG CODE
MAX5953AUTM+
PART
48 TQFN
T4877-6
MAX5953BUTM+
48 TQFN
T4877-6
MAX5953CUTM+
48 TQFN
T4877-6
MAX5953DUTM+
48 TQFN
T4877-6
Operating junction temperature range is 0°C to +125°C.
+Denotes lead-free package.
Pin Configuration and Typical Operating Circuit appear at
end of data sheet.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at
1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.
1
MAX5953A/MAX5953B/MAX5953C/MAX5953D
General Description
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
ABSOLUTE MAXIMUM RATINGS
V+ to VEE ................................................................-0.3V to +90V
OUT, PGOOD, PGOOD to VEE .....................-0.3V to (V+ + 0.3V)
RCLASS, GATE to VEE ...........................................-0.3V to +12V
UVLO to VEE ............................................................ -0.3V to +8V
PGOOD to OUT ........................................... -0.3V to (V+ + 0.3V)
HVIN, INBIAS, DRNH, XFRMRH,
XFRMRL to GND.................................................-0.3V to +80V
BST to GND ........................................................... -0.3V to +95V
BST to XFRMRH .................................................... -0.3V to +12V
PGND to GND .......................................................-0.3V to +0.3V
DCUVLO, RAMP, CSS, OPTO, FLTINT, RCFF,
RTCT to GND..................................................... -0.3V to +12V
SRC, CS to GND...................................................... -0.3V to +6V
REGOUT, DRVIN to GND .......................................-0.3V to +12V
REGOUT to HVIN .................................................. -80V to +0.3V
REGOUT to INBIAS ............................................... -80V to +0.3V
PPWM to GND....................................-0.3V to (VREGOUT + 0.3V)
Maximum Input/Output Current (Continuous)
OUT to VEE ....................................................................500mA
V+, RCLASS to VEE .........................................................70mA
UVLO, PGOOD, PGOOD to VEE .....................................20mA
GATE to VEE ....................................................................80mA
REGOUT to GND ............................................................50mA
DRNH, XFRMRH, XFRMRL, SRC to GND (Average),
TJ = +125°C..................................................................0.9A
PPWM to GND ..............................................................±20mA
Continuous Power Dissipation* (TA = +70°C)
48-Pin TQFN 7mm X 7mm
(derate 27.8mW/°C above +70°C) .............................2222mW
θJA ................................................................................36°C/W
Operating Ambient Temperature Range ................0°C to +85°C
Operating Junction Temperature Range ..............0°C to +125°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-60°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
*As per JEDEC 51 standard.
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(VIN = (V+ - VEE) = 48V, GATE = PGOOD = PGOOD = unconnected, GND = OUT, HVIN = V+, UVLO = VEE, TJ = 0°C to +125°C, unless
otherwise noted. Typical values are at TJ = +25°C. All voltages are referenced to VEE, unless otherwise noted.) (Note 1)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
10
µA
POWERED DEVICE (PD) INTERFACE
DETECTION MODE
Input Offset Current
Effective Differential Input
Resistance (Note 3)
IOFFSET
dR
VIN = 1.4V to 10.1V (Note 2)
VIN = 1.4V, up to 10.1V with 1V step
550
VIN rising (Note 4)
20.8
kΩ
CLASSIFICATION MODE
Classification Current Turn-Off
Threshold
Classification Current
VTH,CLASS
ICLASS
VIN = 12.6V
to 20V,
RDISC =
25.5kΩ
(Notes 5, 6)
21.8
22.5
Class 0, RRCLASS = 10kΩ
0
2
Class 1, RRCLASS = 732Ω
9.17
11.83
Class 2, RRCLASS = 392Ω
17.29
19.71
Class 3, RRCLASS = 255Ω
26.45
29.55
Class 4, RRCLASS = 178Ω
36.6
41.4
V
mA
POWER MODE
Operating Supply Voltage
VIN
VIN = (V+ - VEE)
Operating Supply Current
IIN
Measure at V+, not including RDISC,
GATE = VEE, HVIN = GND = OUT
V
0.4
1
mA
MAX5953A/MAX5953C
37.4
38.6
40.2
MAX5953B/MAX5953D
34.3
35.4
36.9
Default Power Turn-On Voltage
VUVLO, ON
VIN
increasing
Default Power Turn-Off Voltage
VUVLO,OFF
VIN decreasing, MAX5953A/MAX5953C
2
67
30
_______________________________________________________________________________________
V
V
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
(VIN = (V+ - VEE) = 48V, GATE = PGOOD = PGOOD = unconnected, GND = OUT, HVIN = V+, UVLO = VEE, TJ = 0°C to +125°C, unless
otherwise noted. Typical values are at TJ = +25°C. All voltages are referenced to VEE, unless otherwise noted.) (Note 1)
PARAMETER
Default Power Turn-On/Off
Hysteresis Voltage
External UVLO Programming
Range
SYMBOL
VHYST,UVLO
VIN,EX
CONDITIONS
MIN
MAX5953A/MAX5953C
7.1
MAX5953B/MAX5953D
4
MAX5953A/MAX5953C only (Note 7)
12
TYP
MAX
UNITS
V
67
V
UVLO External Reference
Voltage
VREF,UVLO
VUVLO increasing
2.400
2.460
2.522
V
UVLO External Reference
Voltage Hysteresis
VHYST,UVLO
Ratio to VREF, UVLO
19.2
20
20.9
%
VUVLO = 2.460V
-1.5
+1.5
µA
50
440
mV
UVLO Bias Current
IIN,UVLO
UVLO Input Ground-Sense
Threshold
VTH,G,UVLO
(Note 8)
UVLO Input Ground-Sense Glitch
Rejection
7
Power Turn-Off Voltage,
Undervoltage Lockout Deglitch
Time
tOFF_DLY
VIN, VUVLO falling (Note 9)
Isolation Switch n-Channel
MOSFET On-Resistance
RON,ISO
Output current = 300mA, VGATE = 5.6V,
measured between OUT and VEE
Isolation Switch n-Channel
MOSFET Off-Threshold Voltage
GATE Pulldown Switch
Resistance
VGSTH
RG
VGATE - VEE, OUT = V+,
output current < 1µA
µs
0.32
ms
0.6
1.5
0.5
Power-off mode, VIN = +12V
Ω
V
38
80
Ω
GATE Charging Current
IGATE
VGATE = 2V
4.5
10
16.5
µA
GATE High Voltage
VGATE
IGATE = 1µA
5.59
5.76
5.93
V
VOUT - VEE decreasing, VGATE = 5.75V
1.16
1.23
1.31
V
4.62
4.76
PGOOD Assertion VOUT
Threshold (Note 10)
PGOOD, PGOOD Assertion
VGATE Threshold
PGOOD, PGOOD Output Low
Voltage
VOUTEN
VGSEN
Hysteresis
VGATE - VEE increasing
Hysteresis
70
mV
4.91
80
V
mV
ISINK = 2mA, VOUT ≤ (V+ - 5V) (Note 11)
0.2
V
PGOOD Leakage Current
GATE = high, V+ - VOUT = 67V (Note 11)
1
µA
PGOOD Leakage Current
GATE = VEE, PGOOD - VEE = 67V
(Note 11)
1
µA
VOL,PGOOD
_______________________________________________________________________________________
3
MAX5953A/MAX5953B/MAX5953C/MAX5953D
ELECTRICAL CHARACTERISTICS (continued)
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
ELECTRICAL CHARACTERISTICS (DC-DC Controller)
(All voltages referenced to GND, unless otherwise noted. VHVIN = +48V, CINBIAS = 1µF, CREGOUT = 2.2µF, RRTCT = 25kΩ, CRTCT =
100pF, CBST = 0.22µF, VCSS = VCS = 0V, VRAMP = VDCUVLO = 3V, TJ = 0°C to +125°C, unless otherwise noted. Typical values are at
TJ = +25°C, unless otherwise noted.) (Note 1)
PARAMETER
Input Supply Range
SYMBOL
CONDITIONS
VHVIN
MIN
TYP
MAX
UNITS
76
V
11
OSCILLATOR (RTCT)
PWM Frequency
fS
250
kHz
Maximum PWM Duty Cycle
DMAX
Maximum RTCT Frequency
fRTCTMAX
RTCT Peak Trip Level
VTH,RTCT
RTCT Valley Trip Level
VTL,RTCT
1
V
RTCT Input Bias Current
IIN,RTCT
±1
µA
RTCT Discharge MOSFET
RDS(ON)
RDIS,RTCT
47
%
1
MHz
0.51 x VREGOUT
V
(Note 12)
Sinking 50mA
35
RTCT Discharge Pulse Width
85
Ω
50
ns
110
ns
LOOK-AHEAD LOGIC (PPWM)
PPWM to Output Propagation
Delay
tPPWM
VPPWM rising to VXFRMRL falling
PPWM Output High
VOH,PPWM
Sourcing 2mA
PPWM Output Low
VOL,PPWM
Sinking 2mA
7.0
11.0
V
0.2
V
5.5
V
PWM COMPARATOR (OPTO, RAMP, RCFF)
Common-Mode Input Range
VCM_PWM
0
Input Offset Voltage
10
Input Bias Current
RAMP to XFRMRL Propagation
Delay
-2
mV
+2
µA
From VRAMP (50mV overdrive) rising to
VXFRMRL rising
100
ns
Minimum OPTO Voltage
VCSS = 0V, OPTO sinking 2mA
1.47
V
Minimum RCFF Voltage
RCFF sinking 2mA
2.18
V
tCOMPARATOR
REGOUT LDO (REGOUT)
REGOUT Voltage Set Point
REGOUT Load Regulation
REGOUT Dropout Voltage
VREGOUT
INBIAS unconnected,
VHVIN = 11V to 76V
8.3
8.75
9.2
VINBIAS = VHVIN = 11V to 76V
9.5
10.6
11.0
INBIAS unconnected, VHVIN = 15V,
IREGOUT = 0 to 30mA
0.25
VINBIAS = VHVIN = 15V,
IREGOUT = 0 to 30mA
0.25
INBIAS unconnected, IREGOUT = 30mA
1.25
VINBIAS = VHVIN, IREGOUT = 30mA
1.25
REGOUT Undervoltage
Lockout Threshold
REGOUT rising
REGOUT Undervoltage
Lockout Threshold Hysteresis
REGOUT falling
4
V
V
6.6
7.0
0.7
_______________________________________________________________________________________
7.4
V
V
V
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
(All voltages referenced to GND, unless otherwise noted. VHVIN = +48V, CINBIAS = 1µF, CREGOUT = 2.2µF, RRTCT = 25kΩ, CRTCT =
100pF, CBST = 0.22µF, VCSS = VCS = 0V, VRAMP = VDCUVLO = 3V, TJ = 0°C to +125°C, unless otherwise noted. Typical values are at
TJ = +25°C, unless otherwise noted.) (Note 1)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
SOFT-START (CSS)
Soft-Start Current
ICSS
VCSS = 0V
33
µA
80
µA
2.7
V
0.75
V
INTEGRATING FAULT PROTECTION
FLTINT Source Current
IFLTINT
FLTINT Trip Point
VFLTINT rising
FLTINT Hysteresis
INTERNAL POWER FETs
On-Resistance
RON,POWER
VDRVIN = VBST = 9V,
VXFRMRH = VSRC = 0V, IDS = 50mA
Off-State Leakage Current
0.4
-5
Total Gate Charge Per Power
FET
0.8
Ω
+10
µA
15
nC
HIGH-SIDE DRIVER
Low to High Latency
tLH-HS
Driver delay until FET VGS reaches 0.9 x
(VBST - VXFRMRH) and is fully on
80
ns
High to Low Latency
tHL-HS
Driver delay until FET VGS reaches 0.1 x
(VBST - VXFRMRH) and is fully off
40
ns
Output Drive Voltage
VBST
BST to XFRMRH with high side on
8
V
Low to High Latency
tLH-LS
Driver delay until FET VGS reaches 0.9 x
VDRVIN and is fully on
80
ns
High to Low Latency
tHL-LS
Driver delay until FET VGS reaches 0.1 x
VDRVIN and is fully off
40
ns
LOW-SIDE DRIVER
CURRENT-LIMIT COMPARATOR (CS)
Current-Limit Threshold
Voltage
VILIM
Current-Limit Input Bias
Current
IBILIM
0 < VCS < 0.3V
Propagation Delay to XFRMRL
tdILIM
From VCS rising (10mV overdrive) to
VXFRMRL rising
140
156
-2
172
mV
+2
µA
160
ns
tPPWMD
200
ns
tPWQB
300
ns
BOOST VOLTAGE CIRCUIT (See Figure 9, QB)
Driver Output Delay
One-Shot Pulse Width
QB RDSON
Sinking 20mA
30
60
Ω
THERMAL SHUTDOWN
Shutdown Temperature
TSH
Thermal Hysteresis
TH
Temperature rising
+160
°C
20
°C
_______________________________________________________________________________________
5
MAX5953A/MAX5953B/MAX5953C/MAX5953D
ELECTRICAL CHARACTERISTICS (DC-DC Controller) (continued)
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
ELECTRICAL CHARACTERISTICS (DC-DC Controller) (continued)
(All voltages referenced to GND, unless otherwise noted. VHVIN = +48V, CINBIAS = 1µF, CREGOUT = 2.2µF, RRTCT = 25kΩ, CRTCT =
100pF, CBST = 0.22µF, VCSS = VCS = 0V, VRAMP = VDCUVLO = 3V, TJ = 0°C to +125°C, unless otherwise noted. Typical values are at
TJ = +25°C, unless otherwise noted.) (Note 1)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
1.14
1.26
1.38
UNITS
UNDERVOLTAGE LOCKOUT (DCUVLO)
Threshold Voltage
VREF,DCUVLO
Hysteresis
VHYS,DCUVLO
Input Bias Current
IIN,DCUVLO
VDCUVLO rising
140
VDCUVLO = 3V
-100
V
mV
+100
nA
SUPPLY CURRENT
From VHVIN = 11V to 76V,
VCSS = 0V, VINBIAS = 11V
0.7
1.5
Supply Current
From VINBIAS = 11V to 76V,
VCSS = 0V, VHVIN = 76V
4.4
6.4
Standby Supply Current
VDCUVLO = 0V
From VHVIN = 76V, VOPIO = 4V
mA
7
1
Note 1:
Note 2:
Note 3:
mA
Limits at 0°C are guaranteed by design, unless otherwise noted.
The input offset current is illustrated in Figure 1.
Effective differential input resistance is defined as the differential resistance between V+ and VEE without any external
resistance.
Note 4: Classification current is turned off whenever the IC is in power mode.
Note 5: See Table 2 in the Classification Mode section. RDISC and RRCLASS must be 1%, 100ppm or better. ICLASS includes the IC
bias current and the current drawn by RDISC.
Note 6: See the Thermal Dissipation section.
Note 7: When UVLO is connected to the midpoint of an external resistor-divider with a series resistance of 25.5kΩ (±1%), the turnon threshold set point for the power mode is defined by the external resistor-divider. Make sure the voltage on UVLO does
not exceed its maximum rating of 8V when VIN is at the maximum voltage.
Note 8: When VUVLO is below VTH,G,UVLO, the MAX5953A/MAX5953C set the turn-on voltage threshold internally (VUVLO,ON).
Note 9: An input voltage or VUVLO glitch below their respective thresholds shorter than or equal to tOFF_DLY does not cause the
MAX5953A/MAX5953B/MAX5953C/MAX5953D to exit power-on mode (as long as the input voltage remains above an
operable voltage level of 12V).
Note 10: Guaranteed by design, not tested in production for MAX5953B/MAX5953D.
Note 11: PGOOD references to OUT while PGOOD references to VEE.
Note 12: Output switching frequency is 1/2 oscillator frequency.
IIN
dRi ≅
1V
(VINi + 1 - VINi)
=
(IINi + 1 - IINi) (IINi + 1 - IINi)
IOFFSET ≅ IINi -
VINi
dRi
IINi + 1
dRi
IINi
IOFFSET
VINi
1V
VINi + 1
VIN
Figure 1. Effective Differential Input Resistance/Offset Current
6
_______________________________________________________________________________________
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
IIN + IRDISC
0.3
0.2
0.1
CLASS 4
40
35
CLASS 3
30
25
CLASS 2
20
15
CLASS 1
10
5
0
0
2
4
6
8
0
10
5
10
15
20
25
2.5
2.0
1.5
1.0
0.5
0
30
0
2
4
6
8
INPUT VOLTAGE (V)
INPUT VOLTAGE (V)
INPUT OFFSET CURRENT
vs. INPUT VOLTAGE
NORMALIZED UVLO
vs. TEMPERATURE
PGOOD OUTPUT LOW VOLTAGE
vs. CURRENT
-1.5
-2.0
-2.5
-3.0
1.008
1.006
1.004
1.002
1.000
0.998
200
150
100
0.996
50
0.994
-3.5
10
MAX5953A/B/C/D toc06
-1.0
250
VPGOOD (mV)
-0.5
1.010
MAX5953A/B/C/D toc05
MAX5953A/B/C/D toc04
0
0.992
-4.0
2
4
6
8
10
0
0.990
0
25
50
75
100
0
125
10
15
TEMPERATURE (°C)
ISINK (mA)
OUT LEAKAGE CURRENT
vs. TEMPERATURE
INRUSH CURRENT CONTROL
(VIN = 48V)
DCUVLO THRESHOLD
vs. TEMPERATURE
MAX5953A/B/C/D toc08
VOUT = 48V
100
DCUVLO RISING
VGATE
5V/div
0V
IINRUSH
100mA/div
1
PGOOD
50V/div
0.1
25
50
75
TEMPERATURE (°C)
100
125
1.2800
0V
VOUT TO
VEE
50V/div
10
1.2825
4ms/div
VDCUVLO (V)
MAX5953A/B/C/D toc07
1000
0
5
INPUT VOLTAGE (V)
20
MAX5953A/B/C/D toc09
0
OUT LEAKAGE CURRENT (nA)
3.0
INPUT VOLTAGE (V)
NORMALIZED UVLO
0
INPUT OFFSET CURRENT (µA)
CLASS 0
3.5
MAX5953A/B/C/D toc03
45
EFFECTIVE DIFFERENTIAL INPUT RESISTANCE (MΩ)
0.4
50
MAX5953A/B/C/D toc02
DETECTION CURRENT (mA)
RDISC = 25.5kΩ
CLASSIFICATION CURRENT (mA)
MAX5953A/B/C/D toc01
0.5
1.2775
0A
1.2750
0V
1.2725
0
25
50
75
100
125
TEMPERATURE (°C)
_______________________________________________________________________________________
7
MAX5953A/MAX5953B/MAX5953C/MAX5953D
Typical Operating Characteristics
(VIN = (V+ - VEE) = 48V, GATE = PGOOD = unconnected, GND connected to OUT, HVIN connected to V+, UVLO = V EE, CINBIAS = 1µF,
CREGOUT = 2.2µF, RRTCT = 25kΩ, CRTCT = 100pF, CBST = 0.22µF, TJ = 0°C to +125°C, unless otherwise noted. Typical values are
at TJ = +25°C. All voltages are referenced to VEE, unless otherwise noted.)
CLASSIFICATION CURRENT
EFFECTIVE DIFFERENTIAL INPUT
DETECTION CURRENT
vs. INPUT VOLTAGE
RESISTANCE vs. INPUT CURRENT
vs. INPUT VOLTAGE
Typical Operating Characteristics (continued)
(VIN = (V+ - VEE) = 48V, GATE = PGOOD = unconnected, GND connected to OUT, HVIN connected to V+, UVLO = VEE, CINBIAS = 1µF,
CREGOUT = 2.2µF, RRTCT = 25kΩ, CRTCT = 100pF, CBST = 0.22µF, TJ = 0°C to +125°C, unless otherwise noted. Typical values are
at TJ = +25°C. All voltages are referenced to VEE, unless otherwise noted.)
HVIN AND INBIAS INPUT CURRENT
HVIN STANDBY CURRENT
HVIN INPUT CURRENT
vs. TEMPERATURE
vs. TEMPERATURE
vs. TEMPERATURE
245
210
175
4.5
4.4
140
4.3
105
4.2
4.0
3.5
2.5
2.0
25
50
75
100
125
1.0
0
0
25
50
75
100
50
75
100
TEMPERATURE (°C)
REGOUT VOLTAGE
vs. INPUT VOLTAGE
REGOUT VOLTAGE
vs. TEMPERATURE
REGOUT VOLTAGE
vs. LOAD CURRENT
8.81
8.80
8.79
8.82
8.80
8.78
8.78
8.76
8.77
8.74
8.76
8.72
8.75
VHVIN = 15V
INBIAS FLOATING
GND = VEE
8.80
VREGOUT (V)
8.84
37
50
63
76
8.75
8.70
8.70
24
8.65
0
25
50
75
100
125
0
5
10
15
20
VHIN (V)
TEMPERATURE (°C)
IREGOUT (mA)
REGOUT VOLTAGE
vs. INPUT VOLTAGE
REGOUT VOLTAGE
vs. TEMPERATURE
REGOUT VOLTAGE
vs. LOAD CURRENT
10.72
10.66
10.64
10.71
10.70
10.69
25
30
25
30
10.75
MAX5953A/B/C/D toc18
10.73
VREGOUT (V)
10.68
VHVIN = VINBIAS = 48V
10.74
VHVIN = VINBIAS = 15V
GND = VEE
10.70
VREGOUT (V)
HVIN = INBIAS
GND = VEE
MAX5953A/B/C/D toc17
10.75
MAX5953A/B/C/D toc16
10.70
125
MAX5953A/B/C/D toc15
8.86
VREGOUT (V)
8.82
VHVIN = 48V
INBIAS FLOATING
8.88
8.85
MAX5953A/B/C/D toc14
8.90
MAX5953A/B/C/D toc13
INBIAS FLOATING
GND = VEE
11
25
0
125
TEMPERATURE (°C)
8.83
VREGOUT (V)
0.5
TEMPERATURE (°C)
8.85
8.84
IHVIN
1.5
4.0
0
IINBIAS
3.0
4.1
0
VHVIN = VINBIAS = 76V
4.5
70
35
MAX5953A/B/C/D toc12
4.6
5.0
INPUT CURRENT (mA)
fHVIN
VDCUVLO = 0V
280
INBIAS FLOATING
VHVIN = 76V
REGOUT = DRVIN
4.7
IHVIN (mA)
STANDBY CURRENT (µA)
315
4.8
MAX5953A/B/C/D toc11
350
MAX5953A/B/C/D toc10
385
VREGOUT (V)
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
10.65
10.60
10.68
10.62
10.55
10.67
10.66
10.60
24
37
50
VHIN (V)
8
10.50
10.65
11
63
76
0
25
50
75
TEMPERATURE (°C)
100
125
0
5
10
15
IREGOUT (mA)
_______________________________________________________________________________________
20
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
6.6
FALLING
6.4
6.2
450
400
350
RRTCT = 24.3kΩ
CRTCT = 100pF
300
25
50
75
100
125
32.0
31.5
31.0
0
25
50
75
100
0
125
25
50
75
100
MINIMUM RCFF AND OPTO LEVELS
vs. TEMPERATURE
CURRENT-LIMIT COMPARATOR
THRESHOLD vs. TEMPERATURE
PPWM TO XFRMRL SKEW
vs. TEMPERATURE
0.157
0.155
0.154
0.153
1.50
0.152
1.25
99
50
75
100
125
0
25
50
75
100
TEMPERATURE (°C)
FLTINT CURRENT
vs. TEMPERATURE
FLTINT SHUTDOWN VOLTAGE
vs. TEMPERATURE
2.8
2.7
2.6
VFLTINT (V)
82
81
80
79
RISING
2.4
2.3
2.2
77
2.1
76
2.0
25
50
75
TEMPERATURE (°C)
100
125
25
50
75
100
125
0.7
0.6
0.5
0.4
0.3
0.2
FALLING
0.1
1.9
75
92
POWER MOSFETS RDS(ON)
vs. TEMPERATURE
2.5
78
93
0
RDS(ON) (Ω)
83
94
125
MAX5953A/B/C/D toc26
2.9
MAX5953A/B/C/D toc25
84
95
TEMPERATURE (°C)
TEMPERATURE (°C)
85
96
90
0.150
25
97
91
0.151
1.00
98
MAX5953A/B/C/D toc27
OPTO
0.156
100
125
MAX5953A/B/C/D toc24
0.158
VREGOUT (V)
2.00
HVIN RISING
0.159
PPWM TO XFRMRL SKEW (ns)
MAX5953A/B/C/D toc22
RCFF
1.75
0.160
MAX5953A/B/C/D toc23
TEMPERATURE (°C)
2.25
0
32.5
TEMPERATURE (°C)
2.50
0
33.0
TEMPERATURE (°C)
2.75
IFLTINT (µA)
33.5
200
0
MAX5953A/B/C/D toc21
500
250
6.0
VRCFF (V), VOPTO (V)
RRTCT = 12kΩ
CRTCT = 100pF
550
34.0
SOFT-START CURRENT (µA)
6.8
MAX5953A/B/C/D toc20
7.0
600
OPERATING FREQUENCY (kHz)
RISING
7.2
REGOUT UVLO VOLTAGE (V)
MAX5953A/B/C/D toc19
7.4
SOFT-START CURRENT
vs. TEMPERATURE
OPERATING FREQUENCY
vs. TEMPERATURE
REGOUT UVLO VOLTAGE
vs. TEMPERATURE
0
0
25
50
75
TEMPERATURE (°C)
100
125
0
25
50
75
100
125
TEMPERATURE (°C)
_______________________________________________________________________________________
9
MAX5953A/MAX5953B/MAX5953C/MAX5953D
Typical Operating Characteristics (continued)
(VIN = (V+ - VEE) = 48V, GATE = PGOOD = unconnected, GND connected to OUT, HVIN connected to V+, UVLO = VEE, CINBIAS = 1µF,
CREGOUT = 2.2µF, RRTCT = 25kΩ, CRTCT = 100pF, CBST = 0.22µF, TJ = 0°C to +125°C, unless otherwise noted. Typical values are
at TJ = +25°C. All voltages are referenced to VEE, unless otherwise noted.)
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
Pin Description
PIN
NAME
1, 2, 3, 5, 7, 12, 13, 14, 17,
19, 35, 38, 46, 47, 48
N.C.
4
V+
FUNCTION
No Connection. Not internally connected. Make no electrical connection to these pins.
Positive Input Power. Referenced to VEE.
Undervoltage Lockout Programming Input for PD Interface. UVLO is referenced to VEE.
When UVLO is above its threshold, the device enters the power mode. Connect UVLO to
VEE to use the default undervoltage lockout threshold. Connect UVLO to the center of an
external resistor-divider between V+ and VEE to define a threshold externally. The series
resistance value of the external resistors must add to 25.5kΩ (±1%) and replaces the
detection resistor. To keep the device in undervoltage lockout, drive UVLO between
VTH,G,UVLO and VREF,UVLO.
6
(MAX5953A/MAX5953C)
UVLO
6
(MAX5953B/MAX5953D)
N.C.
8
RCLASS
Classification Setting for PD Interface. RCLASS is referenced to VEE. Add a resistor from
RCLASS to VEE to set a PD class (see Tables 1 and 2).
9
GATE
Gate of Internal Isolation n-Channel Power MOSFET. GATE is referenced to VEE. GATE
sources 10µA when the device enters power mode. Connect an external 100V ceramic
capacitor from GATE to OUT to program the inrush current. Drive GATE to VEE to turn off
the internal MOSFET. The detection and classification functions operate normally when
GATE is driven to VEE.
10, 11
VEE
Negative Input Power. Source of the integrated isolation n-channel power MOSFET.
15, 16
OUT
Output Voltage. OUT is referenced to VEE. OUT is connected to the drain of the integrated
isolation n-channel power MOSFET. Connect OUT to GND.
No Connection. Not internally connected. Make no electrical connection to this pin.
18
(MAX5953A/MAX5953B)
PGOOD
Active-High, Open-Drain Power-Good Indicator Output for PD Interface. PGOOD is
referenced to OUT. PGOOD goes high impedance when VOUT is within 1.2V of VEE and
when VGATE is 5V above VEE. Otherwise, PGOOD is internally pulled to OUT (given that
VOUT is at least 5V below V+). PGOOD can be connected directly to CSS or DCUVLO to
enable/disable the DC-DC converter.
18
(MAX5953C/MAX5953D)
PGOOD
Active-Low, Open-Drain Power-Good Indicator Output for PD Interface. PGOOD is
referenced to VEE. PGOOD is pulled to VEE when VOUT is within 1.2V of VEE and when
VGATE is 5V above VEE. Otherwise, PGOOD goes high impedance.
20
CS
Current-Sense Input for PWM Controller. CS is referenced to PGND. The current-limit
threshold is internally set to 156mV relative to PGND. The device has an internal noise filter.
If necessary, connect an external RC filter from CS to PGND for additional filtering.
21
PPWM
PWM Pulse Output. Referenced to GND. PPWM leads the internal power MOSFET pulse by
approximately 100ns.
10
22
GND
23
PGND
24
CSS
Signal Ground of PWM Controller. Connect GND to PGND.
Power Ground of the DC-DC Converter Power Stage. Connect PGND to GND.
Soft-Start Timing Capacitor Connection for PWM Controller. CSS is referenced to GND.
Connect a 0.01µF or greater ceramic capacitor from CSS to GND. Connect to PGOOD to
automatically enable the PWM controller from the PD interface.
______________________________________________________________________________________
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
PIN
NAME
FUNCTION
25
OPTO
PWM Comparator Inverting Input. OPTO is referenced to GND. Connect the collector of the
optotransistor to OPTO and a pullup resistor to REGOUT.
26, 27
SRC
Source Connection of Low-Side Power MOSFET in the Two-Switch Power Stage of the DCDC Converter. Connect SRC to PGND with a low-value resistor for current limiting.
28, 29
XFRMRL
Low-Side Connection for the Isolation Transformer. Drain terminal of low-side power
MOSFET in the two-switch power stage of the DC-DC converter.
30
DRVIN
Supply Input for the Gate-Driver of Internal Power MOSFETs. DRVIN is referenced to
PGND. Bypass DRVIN with at least 0.1µF to PGND. Connect DRVIN to REGOUT.
31, 32
XFRMRH
33, 34
DRNH
36
BST
Boost Input for the DC-DC Converter. BST is the boost connection point for the high-side
MOSFET driver. Connect a minimum 0.1µF capacitor from BST to XFRMRH with short and
wide PC board traces.
37
DCUVLO
DC-DC Converter Undervoltage Lockout Input. DCUVLO is referenced to GND. Connect a
resistor-divider from HVIN to DCUVLO to GND to set the UVLO threshold.
39
HVIN
DC-DC Converter Positive Input Power Supply. HVIN is referenced to GND. Connect HVIN
to V+.
40
INBIAS
41
High-Side Connection for the Isolation Transformer. Source connection of high-side power
MOSFET in the two-switch power stage of the DC-DC converter.
Drain Connection of High-Side MOSFET in the Two-Switch Power Stage of the DC-DC
Converter. Connect DRNH to the most positive rail of the input supply. Bypass DRNH
appropriately to handle the heavy switching current through the transformer.
Input from the Rectified Bias Winding to the DC-DC Converter. INBIAS is referenced to
GND. INBIAS is the input to the internal linear voltage regulator (REGOUT).
Internal Regulator Output. REGOUT is used for the DC-DC converter gate driver. REGOUT
is referenced to GND. VREGOUT is always present as long as HVIN is powered with a
REGOUT
voltage above the DCUVLO threshold. Bypass REGOUT to GND with a minimum 2.2µF
ceramic capacitor.
RTCT
Oscillator Frequency Set Input for the PWM Controller. RTCT is referenced to GND.
Connect a resistor from RTCT to REGOUT and a ceramic capacitor from RTCT to GND to
set the oscillator frequency.
43
FLTINT
Fault Integration Input for PWM Controller. FLTINT is referenced to GND. During persistent
current-limit faults, a capacitor connected to FLTINT is charged with an internal 80µA
current source. Switching is terminated when VFLTINT reaches 2.7V. An external resistor
connected in parallel discharges the capacitor. Switching resumes when VFLTINT drops
to 1.9V.
44
RCFF
Feed-Forward Input for PWM Controller. RCFF is referenced to GND. To generate the PWM
ramp, connect a resistor from RCFF to HVIN and a capacitor from RCFF to GND.
45
RAMP
Ramp Sense Input for PWM Controller. Connect RAMP to RCFF.
—
EP
42
Exposed Paddle. EP is internally unconnected and must be connected to VEE externally.
To improve power dissipation, solder the exposed paddle to a copper pad on the PC
board.
______________________________________________________________________________________
11
MAX5953A/MAX5953B/MAX5953C/MAX5953D
Pin Description (continued)
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
Typical Application Circuit
POWER-OVER
SIGNAL PAIRS
3
VREG
Rx
6
1
PHY
2
-48VRTN
RJ-45
SGND
Tx
+
+
-
-
4
5
7
8
POWER-OVER
SPAIR PAIRS
Figure 2. RJ-45 Connector, PoE Magnetic, and Input Diode Bridges
12
______________________________________________________________________________________
-48V
______________________________________________________________________________________
-48V
D1
60V
C1
68nF
C3
220pF
R5
200kΩ
R3
(RDISC)
25.5kΩ
C4
4.7µF
C2
22µF
63V
OUT
GATE
DRVIN
REGOUT
RCFF
RAMP
VEE
RCLASS
UVLO
C6
0.1µF
R6
24.9kΩ
16
9
30
41
44
45
10
8
6
V+
R8
OPEN
R9
1MΩ
RTCT
42
FLTINT
43
CSS
C7
100pF
24
C8
0.1µF
22
GND
25
OPTO
MAX5953A
CS
20
PGND
C9
220pF
PGND
23
21
BST
PPWM
SRC
R12
604Ω
C10
0.33µF
R11
0.1Ω
INBIAS
XFRMRL
XFRMRH
26, 27
R10
100Ω
DRNH
33, 34
*R1 AND R2 ARE OPTIONAL AND WHEN USED, THEY MUST TOTAL 25.5kΩ AND REPLACE R3, 25.5kΩ.
R7
1.78kΩ
C5
6800pF
R4
(RRCLASS)
255Ω
R2*
OPEN
R1*
OPEN
4
HVIN
39
40
28, 29
31, 32
36
C15
1µF
C
E
R13
15Ω
11T
D3
25T
GND
COMP
FB
LED
C16
0.15µF
D6
D2
U2
FOD2712
C11
0.1µF
C17
0.047µF
22T
R16
562Ω
C14
0.0047µF
C12A
47µF
D4
R15
16.2kΩ
R14
143kΩ
C12B
47µF
SGND
C13
0.1µF
OUT
MAX5953A/MAX5953B/MAX5953C/MAX5953D
-48VRTN
37
DCUVLO
18
R16
316kΩ
PGOOD
R17
14.7kΩ
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
Figure 3. Typical Application Circuit
13
14
-48V
D1
60V
-48VRTN
C1
68nF
R3
(RDISC)
25.5kΩ
______________________________________________________________________________________
16
9
30
41
44
45
10
8
6
OUT
GATE
DRVIN
REGOUT
RCFF
RAMP
VEE
RCLASS
UVLO
V+
RTCT
42
FLTINT
43
CSS
24
22
GND
25
OPTO
MAX5953A
23
20
CS
DRNH
33, 34
PGND
PGND
HVIN
*R1 AND R2 ARE OPTIONAL AND WHEN USED, THEY MUST TOTAL 25.5kΩ AND REPLACE R3, 25.5kΩ.
RRCLASS
R2*
R1*
4
37
DCUVLO
18
PGOOD
39
26, 27
SRC
INBIAS
XFRMRL
XFRMRH
BST
PPWM
21
40
28, 29
31, 32
36
C
E
FB
GND
COMP
U2
FOD2712
LED
SGND
VOUT
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
Figure 4. For higher power applications, the MAX5953A/MAX5953B/MAX5953C/MAX5953D can be used in a two-switch forward
converter configuration
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
PD Interface
The MAX5953A/MAX5953B/MAX5953C/MAX5953D
include complete interface function for a PD to comply
with the IEEE 802.3af standard in a PoE system. They
provide the PD with a detection signature, a classification signature, and an integrated isolation switch with
programmable inrush current control. An integrated
MOSFET provides PD isolation during detection and
classification. All devices guarantee a leakage current
offset of less than 10µA during the detection phase. A
programmable current limit prevents high inrush current during power-on. The device features power-mode
UVLO with wide hysteresis and long deglitch time to
compensate for twisted-pair-cable resistive drop and to
assure glitch-free transition between detection, classification, and power-on/-off phases. The MAX5953A/
MAX5953C have an adjustable UVLO threshold with
the default value compliant to the 802.3af standard,
while the MAX5953B/MAX5953D have a lower and
fixed UVLO threshold compatible with some legacy
pre-802.3af PSE.
Table 1. PD Power Classification/
RRCLASS Selection
CLASS
USAGE
RRCLASS
(Ω)
MAXIMUM POWER
USED BY PD (W)
0
Default
10k
0.44 to 12.95
1
Optional
732
0.44 to 3.84
2
Optional
392
3.84 to 6.49
3
Optional
255
6.49 to 12.95
4
Not
Allowed
178
Reserved*
*Class 4 reserved for future use.
Operating Modes
Depending on the input voltage (VIN = V+ - VEE), the PD
front-end section of the MAX5953A/MAX5953B/
MAX5953C/MAX5953D operate in three different modes:
PD detection signature, PD classification, and PD power.
All voltage thresholds are designed to operate with or
without the optional diode bridge while still complying
with the IEEE 802.3af standard (see Figure 2).
Detection Mode (1.4V ≤ VIN ≤ 10.1V)
In detection mode, the power source equipment (PSE)
applies two voltages on VIN in the range of 1.4V to 10.1V
(1V step minimum), and records the corresponding current measurements at those two points. The PSE then
computes ∆V/∆I to ensure the presence of the 25.5kΩ
signature resistor. In this mode, most interface circuitry
of the MAX5953A/MAX5953B/MAX5953C/MAX5953D is
off and the offset current is less than 10µA.
Classification Mode (12.6V ≤ VIN ≤ 20V)
In the classification mode, the PSE classifies the PD
based on the power consumption required by the PD.
This allows the PSE to efficiently manage power distribution. The IEEE 802.3af standard defines five different
classes as shown in Table 1. An external resistor
(RRCLASS) connected from RCLASS to VEE sets the
classification current.
The PSE determines the class of a PD by applying a
voltage at the PD input and measuring the current
sourced out of the PSE. When the PSE applies a voltage between 12.6V and 20V, the IC exhibits a current
characteristic with values indicated in Table 2. The PSE
uses the classification current information to classify
the power requirement of the PD. The classification current includes the current drawn by the 25.5kΩ detection signature resistor and the supply current of the IC
so the total current drawn by the PD is within the IEEE
802.3af standard figures. The classification current is
turned off whenever the device is in power mode.
Table 2. Setting Classification Current
CLASS
RRCLASS
(Ω)
VIN* (V)
CLASS CURRENT SEEN AT VIN (mA)
MIN
IEEE 802.3af PD CLASSIFICATION
CURRENT SPECIFICATION (mA)
MAX
MIN
MAX
0
10k
12.6 to 20
0
2.00
0
4
1
732
12.6 to 20
9.17
11.83
9
12
2
392
12.6 to 20
17.29
19.71
17
20
3
255
12.6 to 20
26.45
29.55
26
30
4
178
12.6 to 20
36.60
41.40
36
44
*VIN is measured across the MAX5953A/MAX5953B/MAX5953C/MAX5953D input pins (V+ - VEE), which do not include the diode
bridge voltage drop.
______________________________________________________________________________________
15
MAX5953A/MAX5953B/MAX5953C/MAX5953D
Detailed Description
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
Power Mode
During power mode, when VIN rises above the undervoltage lockout threshold (VUVLO,ON), the IC gradually turns
on the internal n-channel MOSFET Q1 (see Figure 8).
The IC charges the gate of Q1 with a constant current
source (10µA, typ). The drain-to-gate capacitance of Q1
limits the voltage rise rate at the drain of the MOSFET,
thereby limiting the inrush current. To further reduce the
inrush current, add external drain-to-gate capacitance
(see the Inrush Current Limit section). When the drain of
Q1 is within 1.2V of its source voltage and its gate-tosource voltage is above 5V, the MAX5953A/MAX5953B
assert the PGOOD output (MAX5953C/MAX5953D assert
the PGOOD output). The IC has a wide UVLO hysteresis
and turn-off deglitch time to compensate for the high
impedance of the twisted-pair cable.
Undervoltage Lockout for PD Interface
The IC operates up to a 67V supply voltage with a default
UVLO turn-on (VUVLO,ON) set at 38.6V (MAX5953A/
MAX5953C) or 35.4V (MAX5953B/MAX5953D) and a
UVLO turn-off (VUVLO,OFF) set at 30V. The MAX5953A/
MAX5953C have an adjustable UVLO threshold using a
resistor-divider connected to UVLO (see Figure 3). When
the input voltage goes below the UVLO threshold for
more than tOFF_DLY, the MOSFET turns off.
To adjust the UVLO threshold, connect an external
resistor-divider from V+ to UVLO to VEE. Use the following equations to calculate R1 and R2 for a desired
UVLO threshold:
R2 = 25.5kΩ ×
VREF,UVLO
VIN,EX
R1 = 25.5kΩ − R2
where VIN,EX is the desired UVLO threshold. Since the
resistor-divider replaces the 25.5kΩ PD detection resistor, ensure that the sum of R1 and R2 equals 25.5kΩ
±1%. When using the external resistor-divider, MAX5953A/
MAX5953C have an external reference voltage hysteresis
of 20% (typ). In other words, when UVLO is programmed
externally, the turn-off threshold is 80% (typ) of the new
UVLO threshold.
Inrush Current Limit
The IC charges the gate of the internal MOSFET with a
constant current source (10µA, typ). The drain-to-gate
capacitance of the MOSFET limits the voltage rise rate
at the drain, thereby limiting the inrush current. Add an
external capacitor from GATE to OUT to further reduce
the inrush current. Use the following equation to calculate the inrush current:
16
IINRUSH = IG ×
COUT
CGATE
The recommended typical inrush current for a PoE
application is 100mA.
PGOOD/PGOOD Output
PGOOD is an open-drain, active-high logic output.
PGOOD goes high impedance when V OUT is within
1.2V of V EE and when GATE is 5V above V EE .
Otherwise, PGOOD is pulled to VOUT (given that VOUT
is at least 5V below V+). Connect PGOOD directly to
CSS to enable/disable the DC-DC converter. PGOOD is
an open-drain, active-low logic output. PGOOD is
pulled to V EE when V OUT is within 1.2V of V EE and
when GATE is 5V above VEE. Otherwise, PGOOD goes
high impedance. Connect a 100kΩ pullup resistor from
PGOOD to V+ if needed.
Thermal Dissipation
Thermal shutdown limits total power dissipation in the
IC. If the junction temperature exceeds +160°C, thermal shutdown is enabled to turn off the MAX5953A/
MAX5953B/MAX5953C/MAX5953D, allowing the IC to
cool. The IC turns on after the junction temperature
cools by 20°C.
DC-DC Converter
The MAX5953A/MAX5953B/MAX5953C/MAX5953D isolated PWM power ICs feature integrated switching power
MOSFETs connected in a voltage-clamped, two-transistor, power-circuit configuration. These devices can be
used in both forward and flyback configurations with a
wide 11V to 76V input voltage range. The voltageclamped power topology enables full recovery of stored
magnetizing and leakage inductive energy for enhanced
efficiency and reliability. A look-ahead signal for driving
secondary-side synchronous rectifiers can be used to
increase efficiency. A wide array of protection features
include UVLO, overtemperature shutdown, and short-circuit protection with hiccup current-limit for enhanced
performance and reliability. Operation up to 500kHz
allows smaller external magnetics and capacitors.
Power Topology
The two-switch forward-converter topology offers outstanding robustness against faults and transformer saturation while affording efficient use of 0.4Ω power
MOSFETs. Voltage-mode control with feed-forward
compensation allows the rejection of input supply disturbances within a single cycle similar to that of currentmode controlled topologies.
______________________________________________________________________________________
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
external resistive divider (R16 and R17) connected to
DCUVLO (see Figure 3). Use the following equation to
calculate R16 and R17:
Voltage-Mode Control and the PWM Ramp
where VDCUVLOIN is the desired input voltage lockout
level and VDCUVLO is the undervoltage lockout threshold (1.25V, typ). Select the R17 resistance value
between 100kΩ and 500kΩ.
For voltage-mode control, the feed-forward PWM ramp
is generated at RCFF. From RCFF, connect a capacitor
to GND and a resistor to HVIN. The ramp generated is
applied to the noninverting input of the PWM comparator at RAMP and has a minimum voltage of approximately 2V. The slope of the ramp is determined by the
voltage at HVIN and affects the overall loop gain. The
ramp peak must remain below the 5.5V dynamic range
of RCFF. Assuming the maximum duty cycle approaches 50% at a minimum input voltage (PWM UVLO turnon threshold), use the following formula to calculate the
minimum value of either the ramp capacitor or resistor:
RRCFF × CRCFF ≥
VIN,EX
2 × fS × VR(P−P)
where fS is the switching frequency, VR(P-P) is the peakto-peak ramp voltage (2V, typ). Select RRCFF resistance
value between 200kΩ and 600kΩ.
Maximize the signal-to-noise ratio by setting the ramp
peak as high as possible. Calculate the low-frequency,
small-signal gain of the power stage (the gain from the
inverting input of the PWM comparator to the output)
using the following formula:
GPS = NSP x RRCFF x CRCFF x fS
where NSP is the secondary to primary power transformer turns ratio.
Secondary-Side Synchronization
The MAX5953A/MAX5953B/MAX5953C/MAX5953D
provide convenient synchronization for optional secondary-side synchronous rectifiers. Figure 5 shows the
connection diagram with a high-speed optocoupler.
Choose an optocoupler with a propagation delay of
less than 80ns. The synchronizing pulse is generated
approximately 110ns ahead of the main pulse that drives the two power MOSFETs.
⎛ R16 ⎞
VDCUVLOIN = VDCUVLO × ⎜1 +
⎟
⎝ R17 ⎠
Optocoupled Feedback
Isolated voltage feedback is achieved by using an
optocoupler as shown in Figure 3. Connect the collector of the optotransistor to OPTO and a pullup resistor
between OPTO and REGOUT.
Internal Regulators
As soon as power is provided to HVIN, internal power
supplies power the DCUVLO detection circuitry.
REGOUT is used to drive the internal power MOSFETs.
Bypass REGOUT to GND with a minimum 2.2µF ceramic capacitor. The HVIN LDO steps down VHVIN to a
nominal output voltage (VREGOUT) of 8.75V. A second
parallel LDO powers REGOUT from INBIAS. A tertiary
winding connected through a diode to INBIAS powers
up REGOUT once switching commences. This powers
REGOUT to 10.5V (typ) and shuts off the current flowing from HVIN to REGOUT. This results in a lower onchip power dissipation and higher efficiency.
MAX5953A
MAX5953B
MAX5953C
MAX5953D
+5V
R
PPWM
PGND
C
Undervoltage Lockout for DC-DC Converter
Connect PGOOD to DCUVLO to ensure the PD interface
is ready prior to the DC-DC converter. The DCUVLO
block monitors the input voltage at HVIN through an
Figure 5. Secondary-Side Synchronous Rectifier Driver Using a
High-Speed Optocoupler
______________________________________________________________________________________
17
MAX5953A/MAX5953B/MAX5953C/MAX5953D
The two-switch power topology recovers energy stored
in both the magnetizing and the parasitic leakage inductances of the transformer. The Typical Application
Circuit, Figure 3, shows the schematic diagram of a -48V
input flyback converter using the MAX5953A. Figure 4
shows the schematic diagram of a -48V input forward
converter and a 5V, 3A output isolated power supply.
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
Soft-Start
Program the MAX5953A/MAX5953B/MAX5953C/
MAX5953D soft-start with an external capacitor (CCSS)
connected between CSS and GND. When the device
turns on, C CSS charges with a constant current of
33µA, ramping up to 7.3V. During this time, the feedback input (OPTO) is clamped to VCSS + 0.6V. This initially holds the duty cycle lower than the value the
regulator imposes, thus preventing voltage overshoot at
the output. When the IC turns off, the soft-start capacitor internally discharges to GND.
I
×t
CFLTINT ≅ FLTINT SH
1.4
where IFLTIN is typically 80µA, and tSH is the desired
ignore time during which current-limit events from the
current-limit comparator are ignored.
This is an approximate formula; some testing may be
required to fine tune the actual value of the capacitor.
Calculate the approximate bleed resistor needed for
the desired recovery time using the following formula:
Oscillator
The oscillator is externally programmable through a
resistor connected from RTCT to REGOUT and a
capacitor connected from RTCT to GND. The PWM frequency is one-half the frequency seen at RTCT with a
50% duty cycle. Use the following formula to calculate
the oscillator components:
RRTCT ≅
1
⎛
⎞
VREGOUT
2fs (CRTCT + CPCB )In⎜
⎟
⎝ VREGOUT − VTH,RTCT ⎠
where CPCB is the stray capacitance on the PC board
(14pF, typ), VTH,RTCT is the RTCT peak trip level, and
fS is the switching frequency.
Integrating Fault Protection
The integrating fault protection feature allows the IC to
ignore transient overcurrent conditions for a programmable amount of time, giving the power-supply time to
behave like a current source to the load. This can happen, for example, under load-current transients when
the control loop requests maximum current to keep the
output voltage from going out of regulation. The ignore
time is programmed externally by connecting a capacitor from FLTINT to GND. Under sustained overcurrent
faults, the voltage across this capacitor ramps up
toward the FLTINT shutdown threshold (2.7V, typ).
When V FLTINT reaches the shutdown threshold, the
power supply shuts down. A high-value bleed resistor
connected in parallel with the FLTINT capacitor allows
the capacitor to discharge toward the restart threshold
(1.9V, typ). FLTINT drops to the restart threshold allowing for soft-starting the supply again.
The fault integration circuit works by forcing an 80µA
current into FLTINT for one clock cycle every time the
current-limit comparator ILIM (Figure 9) trips. Use the
following formula to calculate the approximate capacitor needed for the desired shutdown time:
18
RFLTINT ≅
tRT
CFLTINT × 0.3514
where tRT is the desired recovery time.
Choose tRT ≥ 10 x tSH. Typical values for tSH can range
from a few hundred microseconds to a few milliseconds.
Shutdown
Shut down the controller section of the IC by driving
DCUVLO to GND using an open-collector or open-drain
transistor connected to GND. The DC-DC converter section shuts down if REGOUT is below its DCUVLO level.
Current-Sense Comparator
The current-sense (CS) comparator and its associated
logic limit the peak current through the internal MOSFET.
Current is sensed at CS as a voltage across a sense
resistor between the source of the MOSFET and GND.
The power MOSFET switches off when the voltage at
CS reaches 156mV. Select the current-sense resistor,
RSENSE, according to the following equation:
RSENSE = 0.156V / ILimPrimary
where ILimPrimary is the maximum peak primary-side
current.
To reduce switching noise, connect CS to an external
RC lowpass filter for additional filtering (Figure 3).
Applications Information
Design Example
Design Example 1: PD with three-output flyback DCDC converter
Figure 6 shows an isolated three-output flyback DC-DC
converter. It provides output voltages of 10V at 30mA,
5.1V at 1.8A, and 2.55V at 5.4A.
Design Example 2: PD with nonisolated step-down
(buck) converter
Figure 7 shows a buck converter with 12V, 0.75A output. Caution: this converter does not have active current limit.
______________________________________________________________________________________
______________________________________________________________________________________
-48V
D1
56.7V
GATE
C1
0.068µF
-48VOUT
R15
210kΩ
C2
100pF
INBIAS
R3
(RDISC)
25.5kΩ
C3
2.2µF
R6
210kΩ
R5
210kΩ
C10
22µF
63V
OUT
GATE
DRVIN
REGOUT
RCFF
RAMP
VEE
RCLASS
UVLO
C5
1000pF
R7
25.5kΩ
16
9
30
41
44
45
10
8
6
V+
R8
1MΩ
RTCT
42
FLTINT
43
CSS
C6
100pF
24
C7
0.01µF
22
GND
25
OPTO
MAX5953A
U1
C8
100pF
PGND
23
20
CS
BST
PPWM
21
SRC
R14
470Ω
C13
0.22µF
R10
0.18Ω
INBIAS
XFRMRL
XFRMRH
26, 27
R9
1kΩ
DRNH
33, 34
*R1 AND R2 ARE OPTIONAL AND WHEN USED, THEY MUST TOTAL 25.5kΩ AND REPLACE R3, 25.5kΩ.
R11
2kΩ
C4
4700pF
R4
(RCL)
255Ω
R2*
0Ω
R1*
OPEN
4
HVIN
39
PPWM
C12
0.1µF
2
3
D6
C
E
T1
D12
D11
GND
N.C.
1, 4
5
8
LED
U2
7
FOD2712 FB
6
COMP
C19
0.068µF
C11
0.1µF
C9
0.22µF
INBIAS
R25
OPEN
40
28, 29
31, 32
36
-48VOUT
D4
R18
22Ω
R17
22Ω
G2
R21
2.52kΩ
R20
2.74kΩ
R23
1MΩ
N3
1kΩ N1
R19
G1
R24
1kΩ
R22
221Ω
N4
N2
C20
0.068µF
A2
A1
D3
R16
1kΩ
D2
T2
PA0264
C24
0.1µF
A2
A2
G2
A1
G1
D5
A1
VOUT2
C15
22µF
C23
220µF
-48VOUT
C18
2200pF
VOUT2
C22
220µF
C17
220µF
C16
VOUT3 100pF
C14
0.47µF
C21
0.1µF
D8
R27
10kΩ
R28
10kΩ
VOUT1 (10V AT 30mA)
D9
VOUT3
D7
C17A
100µF
C26
0.1µF
D10
RTN
VOUT3 (2.55V AT 5.4A)
VOUT2 (5.1V AT 1.8A)
MAX5953A/MAX5953B/MAX5953C/MAX5953D
-48VRTN
37
DCUVLO
18
R16
316kΩ
PGOOD
R17
14.7kΩ
PPWM
R6
100Ω
C25
0.1µF
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
Figure 6. PD with Three-Output Flyback DC-DC Converter
19
20
-48V
D1
60V
-48VRTN
0.5A
C1
68nF
C3
100pF
R3
210kΩ
R1
(RDISC)
25.5kΩ
C4
2.2µF
C2
22µF
63V
C5
4700pF
R2
(RRCLASS)
255Ω
OUT
GATE
DRVIN
C6
150pF
R5
1kΩ
R6
100kΩ
RTCT
42
FLTINT
43
REGOUT
RCFF
RAMP
VEE
RCLASS
V+
R4
26.7kΩ
16
9
30
41
44
45
10
8
4
CSS
C7
100pF
24
R8
316kΩ
C8
0.022µF
22
PGOOD
GND
25
OPTO
MAX5953A
U1
37
DCUVLO
18
R9
14.7kΩ
PGOOD
PGOOD
23
20
CS
DRNH
33, 34
PGND
PGND
HVIN
39
26, 27
SRC
R10
OPEN
C9
OPEN
INBIAS
XFRMRL
XFRMRH
BST
PPWM
21
40
28, 29
31, 32
36
C13
1µF
R7
3.9kΩ
TL431CD
C10
0.022µF
D4
L1
220µH
C16
0.01µF
R13
14.3kΩ
C11
22µF
R12
1.78kΩ
R11
6.81kΩ
GND
C14
0.15µF
C12
1µF
OUT
12V, 0.75A
C15
0.03µF
R16
4.99kΩ
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
Figure 7. PD with Nonisolated Step-Down (Buck) Converter
______________________________________________________________________________________
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
COMPONENT
Power FETS
Current-Sense Resistors
Diodes
Capacitors
Magnetics
SUPPLIERS
WEBSITE
International Rectifier
www.irf.com
Fairchild
www.fairchildsemi.com
Vishay-Siliconix
www.vishay.com/brands/siliconix/main.html
Dale-Vishay
www.vishay.com/brands/dale/main.html
IRC
www.irctt.com/pages/index.cfm
ON Semi
www.onsemi.com
General Semiconductor
www.gensemi.com
Central Semiconductor
www.centralsemi.com
Sanyo
www.sanyo.com
Taiyo Yuden
www.t-yuden.com
AVX
www.avxcorp.com
Coiltronics
www.cooperet.com
Coilcraft
www.coilcraft.com
Pulse Engineering
www.pulseeng.com
Layout Recommendations
All connections carrying pulsed currents must be very
short, as wide as possible, and have a ground plane as
a return path. The inductance of these connections
must be kept to a minimum due to the high di/dt of the
currents in high-frequency-switching power converters.
Current loops must be analyzed in any layout proposed, and the internal area kept to a minimum to
reduce radiated EMI. Ground planes must be kept as
intact as possible.
______________________________________________________________________________________
21
MAX5953A/MAX5953B/MAX5953C/MAX5953D
Table 3. Component Suppliers
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
Block Diagrams
V+
UVLO
REF
2.4V
REF
EN
V+
21.8V
CLASSIFICATION
6.8V
MAX5953A
MAX5953B
MAX5953C
MAX5953D
2.4V, 0.8
HYST
RCLASS
PGOOD**
Q4
39V
VGATE, 6V
1.2V, REF
EN
UVLO*
PGOOD***
5V, REF
Q3
OUT
Q2
38Ω
200mV
Q1
0.6Ω
GATE
*MAX5953A/MAX5953C ONLY.
**MAX5953C/MAX5953D ONLY.
***MAX5953A/MAX5953B ONLY.
VEE
Figure 8. Powered Device Interface Block Diagram
22
______________________________________________________________________________________
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
INBIAS
REGOK
REGOUT
HVIN
REG
DCUVLO
OVT
REF
(1.25V)
REFOK
DCUVLO
DCUVLO
RCFF
1.25V
5V
5V
IFLT
80µA
Q
PPWM
7.5V
D
50Ω
T
R
FLTINT
RAMP
BST
GND
DRNH
OVRLD
2.7V/1.9V
R
80ns
DELAY
Q
LEVEL
SHIFT
0.4Ω
QH
XFRMRH
CPWM
S
OPTO
LEADINGEDGE
DELAY
5V
ONE
SHOT
30Ω
QB
DRVIN
33µA
CLK
Q
T-FF
CSS
SHDN
R
T
XFRMRL
OSC
0.4Ω
THERMAL
SHUTDOWN
OVT
QL
SRC
PGND
OVT
DCUVLO
REFOK
REGOK
OVRLD
50Ω
GND
MAX5953A
MAX5953B
MAX5953C
MAX5953D
GND
RTCT
CS
ILIM
10MHz
150mV
PGND
Figure 9. DC-DC Converter Block Diagram (Voltage-Mode PWM Controller and Two-Switch Power Stage)
______________________________________________________________________________________
23
MAX5953A/MAX5953B/MAX5953C/MAX5953D
Block Diagrams (continued)
24
-48V
D1
60V
-48VRTN
C1
68nF
R3
(RDISC)
25.5kΩ
______________________________________________________________________________________
16
9
30
41
44
45
10
8
6
OUT
GATE
DRVIN
REGOUT
RCFF
RAMP
VEE
RCLASS
UVLO
V+
RTCT
42
FLTINT
43
CSS
24
22
GND
25
OPTO
MAX5953A
U1
DCUVLO
PGOOD
23
DRNH
CS
20
PGND
PGND
HVIN
33, 34
*R1 AND R2 ARE OPTIONAL AND WHEN USED, THEY MUST TOTAL 25.5kΩ AND REPLACE R3, 25.5kΩ.
RRCLASS
R2*
R1*
4
37
18
39
26, 27
SRC
INBIAS
XFRMRL
XFRMRH
BST
PPWM
21
40
28, 29
31, 32
36
C
E
FB
GND
COMP
U2
FOD2712
LED
SGND
OUT
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
Typical Operating Circuit
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
OPTO
SRC
SRC
XFRMRL
XFRMRL
DRVIN
XFRMRH
XFRMRH
DRNH
DRNH
N.C.
BST
TOP VIEW
36 35 34 33 32 31 30 29 28 27 26 25
DCUVLO
37
24
CSS
N.C.
38
23
PGND
HVIN
39
22
GND
INBIAS
40
21
PPWM
REGOUT
41
20
CS
19
N.C.
18
**
17
N.C.
MAX5953A
MAX5953B
MAX5953C
MAX5953D
N.C.
47
14
N.C.
N.C.
48
13
N.C.
2
3
4
5
6
7
8
9
10 11 12
VEE
1
N.C.
+
VEE
OUT
GATE
OUT
15
RCLASS
16
46
N.C.
45
N.C.
*
RAMP
N.C.
44
V+
RCFF
N.C.
43
N.C.
42
N.C.
RTCT
FLTINT
THIN QFN
7mm x 7mm
*UVLO FOR MAX5953A/MAX5953C
N.C. FOR MAX5953B/MAX5953D
** PGOOD FOR MAX5953A/MAX5953B
PGOOD FOR MAX5953C/MAX5953D
Selector Guide
PGOOD or
PGOOD
UVLO
MAX5953A
PGOOD
Adjustable
MAX5953B
PGOOD
Fixed
MAX5953C
PGOOD
Adjustable
MAX5953D
PGOOD
Fixed
PART
Chip Information
PROCESS: BiCMOS
______________________________________________________________________________________
25
MAX5953A/MAX5953B/MAX5953C/MAX5953D
Pin Configuration
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information
go to www.maxim-ic.com/packages.)
E
DETAIL A
32, 44, 48L QFN.EPS
MAX5953A/MAX5953B/MAX5953C/MAX5953D
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
(NE-1) X e
E/2
k
e
D/2
CL
(ND-1) X e
D
D2
D2/2
b
L
E2/2
DETAIL B
e
E2
CL
L
L1
CL
k
CL
L
L
e
A1
A2
e
A
PACKAGE OUTLINE
32, 44, 48, 56L THIN QFN, 7x7x0.8mm
21-0144
26
______________________________________________________________________________________
E
1
2
IEEE 802.3af PD Interface and PWM Controllers
with Integrated Power MOSFETs
PACKAGE OUTLINE
32, 44, 48, 56L THIN QFN, 7x7x0.8mm
21-0144
E
2
2
Revision History
Pages changed at Rev 1: 1, 27
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 27
© 2006 Maxim Integrated Products
M. Quijano
is a registered trademark of Maxim Integrated Products, Inc.
MAX5953A/MAX5953B/MAX5953C/MAX5953D
Package Information (continued)
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information
go to www.maxim-ic.com/packages.)